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Transcript
CONVERSION OF GREENHOUSE GASSES INTO ENERGY
By
Sarah C. Rippe
Advised by
Dr. William Preston
ANT 461, 462
Senior Project
Social Sciences Department
College of Liberal Arts
CALIFORNIA POLYTECHNIC STATE UNIVERSITY
Fall, 2013
TABLE OF CONTENTS
Research Proposal
…………………………………………………………………………
i
Annotated Bibliography ……………………………………………………………………
ii
Outline
…………………………………………………………………………………..
Introduction
………………………………………………………………………………
Greenhouse Gasses
Mitigation
2
………………………………………………………………………………….
8
…………………………………………………………………………...
11
……………………………………………………………………………………
16
Nitrous Oxide
……………………………………………………………………………..
Fluorinated Gasses
Conclusion
………………………………………………………………………..
20
22
……………………………………………………………………………….
24
.……………………………………………………………………………...
26
………………………………………………………………………………….
28
Bibliography
Appendix
1
………………………………………………………………………..
Carbon Dioxide
Methane
iv
Research Proposal
This project is to gather information and gain knowledge on how to convert greenhouse
gasses into energy. The goal is to integrate the information into one comprehensive and concise
resource. I will explain what the greenhouse gasses are to provide a basic context, before I
venture into expressing how individual gasses do harm to the environment and humanity. I will
also include previous findings and processes on how to convert these gasses into energy. My
sincere hope is that my research paper will make people more aware of the how greenhouse
gasses are created, the harm that excess greenhouse gasses cause, and to motivate endeavors to
reduce greenhouse gasses by capturing and converting the gasses into profitable energy. This
research will be accomplished by using literary resources such as books and journal articles. As
this is a contemporary issue, I will utilize reputable and current online sources too.
Annotated Bibliography
Blockstein, David E. and Leo A. Wiegman. The Climate Solutions Consensus. Washington [DC]:
Island Press, 2010. With wit and creativity these authors present what are greenhouse gasses,
especially carbon, and what damage greenhouse gasses have done. The authors include a
condensed history on climate change and the resulting danger to the environment and humanity.
They conclude with the recommended actions on how to address the problems with carbon and
greenhouse gasses. This book correlates with my project by providing ideas into how to battle
greenhouse gasses, and specifically their focus on carbon. In summary it provides a wealth of
information on the topic of greenhouse gasses.
Clean Tech, Clean Profits: Using Effective Innovation and Sustainable Business Practices to Win
in the New Low-carbon Economy. Philadelphia: Kogan Page Ltd, 2010. This book presented an
economic focus on how to handle greenhouse gasses and to make a profit. It was a helpful book
in finding resources and various ways to convert greenhouse gasses into energy, thus helping
with reducing and removing of them.
Dallas, Nick. Green Business Basics: 24 Lessons for Meeting the Challenges of Global Warming.
New York: McGraw-Hill, 2009. Dallas offers readers a straight-forward book about the business
aspect of global warming and greenhouse gasses. He precisely and swiftly goes through: defining
greenhouses gasses, focuses on carbon dioxide, gives a brief history of carbon dioxide and
humanity, and lists various ways of how to mitigate greenhouses gasses. It is a helpful book for
my project because it presents complex topics more simplistically. It aids in understanding this
complicated topic. The book also brings about an awareness and understanding of additional
complex concepts in the project.
Dandekar, Hemalata. "Gobar Gas Plants: How Appropriate Are They?" Economic and Political
Weekly. Vol. 15. Mumbai: Sameeksha Trust, 1980. 887-93. This article was a fascinating read as
it discussed the technology of producing energy from methane gas that is already been used in
India. It gives a first-hand experience on what the locals thought about it and how helpful, or not,
it has been. For my paper this article is helping me to understand if such technology is viable or
helpful. It also features companies already using conversion technology to demonstrate its
feasibility.
Global Weirdness : Severe Storms, Deadly Heat Waves, Relentless Drought, Rising Seas, and the
Weather of the Future. New York: Pantheon Books, 2012. This book is quirky and witty, yet
informational and poignant. It focuses on: what climate change is, what it has done, what it is
doing environmentally and globally, and what is the projected climate change going to cause.
For my project, it presents vital knowledge in regards to the dangers of global warming, and why
it is important to find a way to convert greenhouse gasses into energy. The book also provides me
with the data about reducing the existing greenhouse gasses by capturing their by-products.
Energy is money and money appears to be the universal motivator to act. Hopefully, I will be
able to convey these actions in my paper and perhaps reduce the predicted catastrophes detailed
in this book.
Howell, Derek. Your Solar Energy Home : Including Wind and Methane Applications. Oxford:
Pergamon Press, 1979. Howell provides, in detail, how an individual and company can use
methane as energy. He provides information and blueprints into how precisely one can create a
home or company powered by methane. This citation relates to the project by providing a
thorough explanation of how methane can be converted into energy, and how one can utilize this
method for personal or business use.
Hunter, Christopher, Karel Svoboda, David Baxter, and Maria Gutierrez. "Nitrous Oxide (N2O)
Emissions from Waste and Biomass to Energy Plants."Waste Management & Research, 23.2
(2005): 133-147. This article describes various ways to convert N20 into energy. They explain
where N20 comes from, and a condensed history of N20. They go on to explain why it is
important to capture it to make energy. This article is vitally important to me, because it explains
a way to convert N20 into energy. An issue very difficult to find any information on in relation to
its conversion to useable energy.
Rajaram, Vasudevan, Faisal Zia Siddiqui, M Emran Khan. From Landfill Gas to Energy:
Technologies and Challenges. Leiden, The Netherlands: CRC/Balkema, 2012. This online book
presents a thorough study of how to convert landfill gasses into energy. It helps with the project
by providing information on more technologies that can convert greenhouse gasses into energy,
which is a fundamental part of the paper.
Turner, Martyn, and Brian O'Connell. The Whole World's Watching : Decarbonizing the
Economy and Saving the World. Chichester, West Sussex, England: John Wiley, 2001. This book
presents the issue of climate change with a focus on carbon dioxide, but it suggests how to
convert other gasses into energy, too, such as methane.
U.S Environmental Protection Agency. Inventory of U.S. Greenhouse Gas Emissions and Sinks:
1990-2011. Washington, D.C.: National Service Center for Environmental Publications
(NSCEP), 2013.This report presents graphs and statistics of the United States greenhouse
gasses. They break it down into refined detail and statistics. A bountiful source of data in the
breakdown of each gas and its sources. It is helpful to the project, because it clearly shows where
each gas is coming from, and how much from each source. It is a great resource about the
sources of where greenhouse gasses come from.
Outline
1)
2)
3)
4)
5)
The Title Page
The Table of Contents
The Research Proposal
The Annotated Bibliography
The Outline
A) The Introduction
1) The hook
2) The transition between the hook and the thesis
3) The thesis statement
4) The layout of the paper
B) The Body
1) Part 1
a) What are greenhouse gasses
b) What harm they create to the environment and us
c) What is forecasted if nothing changes
2) Part 2
a) The history of mitigation attempts of greenhouse gasses
b) My proposed mitigation of greenhouse gasses via conversion to energy
3) Part 3
a) Carbon Dioxide:
1) Explain what this gas is
2) How it is created
3) The various ways that this gas can be converted into energy
b) Methane:
1) Explain what this gas is
2) How it is created
3) The various ways that this gas can be converted into energy
c) Nitrous oxide:
1) Explain what this gas is
2) How it is created
3) The various ways that this gas can be converted into energy
d) Fluorinated gasses:
1) Explain what these gasses are
2) How they are created
3) The various ways that these gases can be converted into energy
C) The Conclusion
1) Restate and reinforce the thesis
2) Summary of paper and main points
3) Suggestions for future research
6) The Bibliography
1.
Introduction
What are greenhouse gasses? Are they truly harmful to people and the environment? If
nothing globally changes in mitigating greenhouse gasses will it truly be cataclysmic? Is there
anything being done to address this global issue? Can anything be done to handle these
greenhouse gasses? I hope to address these questions and more with my study of this debated
topic of greenhouse gasses. I propose that greenhouse gasses be converted into energy. Through
this proposal I hope to address one of the biggest hurdles that mitigation of greenhouse gasses
face: motivation. Energy can translate into monetary value for commercial and personal benefits.
If we can reduce the existing greenhouse gasses and capture newly produced gasses by turning
them into profitable and functional energy, perhaps it will provide the motivation to resolve this
issue.
To help obtain this goal information must be compiled into one comprehensive and
concise source. Through the use of literary resources such as books, journal articles, and online
sources I will provide information that is rooted in solid science and break-through technologies.
I will start by answering the question of what greenhouse gasses are to provide a foundation to
support the rest of the paper. I will venture into why we should address this topic in regards to
the harmful effects. I will also address the predicted effects if these gasses are not mitigated.
I will address the current efforts being attempted in mitigating greenhouse gasses. I will
follow this discussion by developing my proposal to converting greenhouse gasses into energy.
The next section of the paper will be devoted to the major individual gasses that compose
the term greenhouse gasses: Carbon Dioxide, Methane, Nitrous Oxide, and Fluorinated gasses.
I will explain what each gas is specifically and how it is created. I will single out how the gas as
a lone component is harmful to the environment and us. I will conclude the individual
assessment of each gas by suggesting various the gas can be converted into energy.
My proposed ideas for the mitigation of greenhouse gasses is followed by the conclusion
of the paper, where I shall summarize the main points. Moreover, I will conclude with
suggestions for future research to continue to address the problems and solutions regarding
greenhouse gasses.
2.
Greenhouse Gasses
The start of this topic begins with
the foundation of what greenhouse
gasses are. They are carbon dioxide,
methane, nitrous oxide, and fluorinated
gasses (see fig. 1). Fluorinated gasses are
composed of three groups of chemical
compounds: “hydrofluorocarbons
(HFCs), perfluorocarbons (PFCs), and
sulfur hexafluoride (SF6)” (U.S
Fig. 1 Global greenhouse gasses emissions by category.
"Global Greenhouse Gas Emissions by Gas". Graph.
Environmental Protection Agency 1-3).
2007. Global Greenhouse Gas Emissions Data.
Environmental Protection Agency. Web. 03 Sept.
These gasses shall be individually
2013.
examined later in the paper. The combination of these gasses are the source of the greenhouse
effect. The greenhouse effect can be described as: the sun bombards the earth with energy, and
the energy that reaches the earth's surface, which was not reflected or already absorbed on the
way to the earth's surface, gets absorbed by the land and oceans. While the oceans and land
absorbs this energy, it also releases heat. As this heat is released and on its way out of the
atmosphere it gets caught by greenhouse gasses. Once this heat is caught by greenhouse gasses
these gasses then act like “a miniature version of what earth as a whole does: heat up, then
radiate some of the heat away” (“Global Weirdness” 26). This process does not allow the heat to“
immediately escape to outer space; it first warms up other air molecules and ultimately warms
the earth itself” (“Global Weirdness” 26). This process is called the greenhouse effect.
It is crucial to discuss the difference between the natural greenhouse effect versus the
greenhouse effect enhanced by humans, because there is a an importance distinction. The natural
greenhouse effect is a process that maintains an inhabitable temperature for our existence. The
man-made greenhouse effect creates an excess of heat that is over loading the natural cycle of the
earth. The problem is not with the earth's natural processes, but the problem is with excessive
greenhouse
gasses created by
humans (see fig.
2). The scientific
term is called:
“anthropogenic
climate change”
(“Global
Fig. 2 Natural greenhouse effect versus human-enhanced greenhouse effect. Weirdness” 28).
“Natural greenhouse effect versus human enhanced greenhouse effect”.
Illustration. n.d.. Climate Change. National Park Services. Web. 03 Sept. 2013.
Anthropogenic climate change is exhibited in the earth's temperatures. Since the 1900's,
the average temperature of the earth's surface has risen 1.4°F, and it is predicted to rise another 2
to 11.5 degrees by the end of this century (U.S Environmental Protection Agency 1-3). The
rising temperatures have already contributed to melting glaciers, rising sea levels, and rising sea
temperatures. Sea levels have already risen “eight inches since 1900” (“Global Weirdness” 83),
which equates to low-land areas having to deal with disappearing land and negative
consequences for both humans and the natural environment. A prime example of these negative
consequences are happening to the Maldives Islands in the Indian Ocean. Since the majority of
their islands have an elevation of zero, the rising sea levels pose a direct threat to their citizen.
To combat the rising levels of the sea the government of the Maldives have built a seawall
around the entire island of Male, and plans to build more around other islands (“Sea Level
Rise”). Another example of the negative consequences from the rising sea levels and
temperature is the habitat of the polar bears. A combination of disappearing glaciers/ice and
rising sea levels, due to the increasing temperature of the sea and earth, has placed the polar
bears as the first animal to become an endangered species because of anthropogenic climate
change (“Global Wierdness” 96). Who will be next?
It is scientifically shown that the excess greenhouse gasses caused by humans is heating
up the earth; this rise in temperature comes with a host of actual and predicted consequences that
will effect the earth's ecosystem:
“mountain glaciers will start to melt, so the rivers they feed will flow differently.
More water will evaporate from both land and oceans, leading to more rain and
snow in some places and more drought in others. As the oceans warm major
currents may speed up or slow down, which would affect weather patterns.
Temperatures at the poles and the equator might change. The winds might start to
blow in different directions changing weather patterns, again. Also, animals and
plants that are in a particular geographic location might have to move somewhere
else to find conditions that they are adapted to, or try to adapt, or just go extinct”
(Global Weirdness” 27-28).
Another concern is the impact these greenhouse gasses will have upon the largest
ecosystem on the planet: the oceans. The concern is that the excess carbon-dioxide is causing the
oceans to become more acidic. These harmful effects on plants and animals that live in the sea,
which in turn effects us.
Already earth is exhibiting the impacts resulting from these greenhouse gasses. One of
the problems that has arisen due to the increased global temperatures is that plant and animal
cycles are being disrupted. There is a startling statistic that the “growing season in the
continental United States is two weeks longer than it was in the 1900's” (“Global Weirdness”
98). Also, these changes have already caused problem in the inherent life-cycle of the cuckoo
bird (“Global Weirdness” 100-102). The cuckoo bird, flying from Africa to the United Kingdom,
relies upon the nests of short-distance migratory birds to lay their eggs in; upon arrival the
cuckoo bird sneaks their eggs into the short-distance bird's nest and it tends to their egg (“Global
Weirdness” 102). With the earlier cycles, it is sometimes too late for the cuckoo bird: the shortdistance birds have already built their nests, and have hatched their young. This leaves no tended
nest for the cuckoo bird to use (“Global Weirdness” 102). Additionally, certain species can adapt
to change better than others, so with these changing ecosystems we are losing the inherent
ecological diversity of specific areas. The outcome of this has already been experienced globally:
“in North America, populations of thirty-nine butterfly species moved 125 miles north. Coldloving plants in the Alps moved higher into the mountains. And sea anemones off the California
coast moved northward” (“Global Weirdness” 108). The bark beetles in Alaska are a another
prime example of how the warming of the globe has caused problems. The bark beetle devastates
the white spruce in Alaska, but was until recently kept in balance by the cold climate. Due to
higher temperatures the bark beetles life cycle has been prolonged, and have consequently
expanded their range, which has allowed the bark beetles to destroy an area equivalent to the size
of Connecticut in just a few years (“Global Weirdness” 104). Not only are the micro-ecosystems
of specific animals and plants being affected, but entire ecosystems around the world are seeing
changes (“Global Weirdness” 103). During the latter half of the 20th century and continuing
today ocean acidity has increased. This has contributed to the demise of coral. For example,
nearly one quarter of the coral in the Indian Ocean have died, and most of the marine life that
depended on it have suffered (“Global Weirdness” 106). Another problem that is happening
globally is the increase in droughts, torrential rains, floods, and other extreme weather. The
Intergovernmental Panel on Climate Change (IPCC) confirms that this is likely and connected to
the problems that are caused by excess greenhouse gasses (“Global Weirdness” 118). The IPCC
defines likely as: “at least a two-thirds probability that something is true” (“Global Weirdness”
118). These impacts may seem inconsequential to humanity, but the reality is the world is
comprised of a multitude of micro-ecosystems that make up our earth's global ecosystem, and
when one micro-ecosystem is harmfully effected it in turn affects others.
Unfortunately these are not the only climate changes caused by humans, there is more.
Not only are temperatures rising, and coral reefs dying, but deserts are expanding, and tropical
cyclones are intensifying (Blockstein and Wiegman 20). The reason that tropical cyclones are
intensifying is due to “an increase of as little as two degrees of warming will produce an increase
in category 4 and category 5 tropical cyclone storms. In addition, the storms impacts on coastal
regions will be exacerbated by sea level rise” (Blockstein and Wiegman 22). These
anthropogenic climate changes are just a sampling of what the increased levels of greenhouse
gasses are currently causing.
If the excessive greenhouse gasses are left unmitigated the future for mankind and the
environment is precarious. Scientific research has already shown that the excessive greenhouse
gasses have already raised the earth's temperature by nearly two degrees. So how does this higher
temperature impact our future? Unfortunately it means many things. A warming as little as two
degrees will “increase the frequency and magnitude of flash flooding in many regions, and largescale floods in the mid and high latitudes because rainstorms will be more intense dropping more
water in less time.” (Blockstein and Weigman 22). Also this increase in temperatures will be a
catalyst for extreme heat events, which causes “human mortality to rise, crops to fail, forests to
die and succumb easily to fire” ( Blockstein and Weigman 22). Additionally, warming will lead
to an increase of “droughts in the mid-latitude continental areas as inland summer drying
becomes more prevalent. Such droughts can lead to vegetation die-offs as the soil dries out, and
drier soil also exacerbates extreme heat waves” ( Blockstein and Weigman 22). Furthermore,
where there is heat and droughts, fires often follow; the frequency and intensity of fires will
increase, too ( Blockstein and Weigman 22). The impact on humanity caused by the increase of
severe weather will “likely inflict exponentially increasing damage on housing, transportation
and agricultural infrastructure” ( Blockstein and Weigman 23). Humanity will be subjected to
increasing “malnutrition (defined as the nonavailability of recommended daily calorie intake),
infectious diseases, episodes of diarrheal diseases, and cases of malaria” ( Blockstein and
Weigman 23). Also it is known that water resource scarcity will rise as water quality decreases
(Blockstein and Weigman 23). Global warming may cause a 20% to 30% extinction of species; a
great shift in global biodiversity and ecosystems. (Blockstein and Weigman 25). It is
scientifically predicated by science that anthropogenic greenhouse gasses will bring about these
cataclysmic events and more by 2100. We must try to improve the mitigation of greenhouse
gasses to lessen the repercussions of the existing and future greenhouse effects.
3.
Mitigation of Greenhouse Gasses
The awareness of greenhouse gasses, and their potential harm have been known for a
long time:
In the 19th century scientists realized that gases in the atmosphere cause a
"greenhouse effect" which affects the planet's temperature. These scientists were
interested chiefly in the possibility that a lower level of carbon dioxide gas might
explain the ice ages of the distant past. At the turn of the century, Svante
Arrhenius calculated that emissions from human industry might someday bring a
global warming. Other scientists dismissed his idea as faulty. In 1938, G.S.
Callendar argued that the level of carbon dioxide was climbing and raising global
temperature, but most scientists found his arguments implausible. It was almost by
chance that a few researchers in the 1950s discovered that global warming truly
was possible. In the early 1960s, C.D. Keeling measured the level of carbon
dioxide in the atmosphere: it was rising fast. Researchers began to take an interest,
struggling to understand how the level of carbon dioxide had changed in the past,
and how the level was influenced by chemical and biological forces. They found
that the gas plays a crucial role in climate change, so that the rising level could
gravely affect our future. (Weart)
It has taken a long time for individual nations to acknowledge that excessive greenhouse
gasses are a problem, despite how long ago they were discovered and the known dangers their
increase present. It has taken a longer time for nations to realize that this is a threat that needed
international cooperation. Thus, endeavors to mitigate greenhouse gasses on an international
scale has been limited. It was in 1979 at the First World Climate Conference where the
beginnings of international concerted effort started.. Afterward attention and action towards
excessive greenhouse gasses has been slow, but gaining more prominence as proof and
consequences are becoming less deniable. These international conferences and the resulting
protocols is a needed global approach to deal with this foreboding topic.
China is currently the leading culprit of producing excessive carbon dioxide. Prior to
China, the United States had been the biggest contributor to the problem, hence the United States
government has taken strides to tackle this issue. For example, on June 25, 2013 President
Obama announced a plan to continue to reduce carbon emissions and to expedite resolutions for
greenhouse gasses. The United States has made efforts through the EPA (Environmental
Protection Agency) to address the problem; these include: “collection emissions data, getting
reductions, evaluating policy options, costs and benefits, advancing the science, partnering
internationally, partnering with states, localities, and tribes, and helping communities adapt” (see
Appendix for more details) (“What is the EPA doing about Climate Change?”).
As a nation, we've have a strong fuel economy standard, doubled renewable energy in the
last year, and have decreased our pollution, but we still have so much more work to do (President
Obama). To continue to cut back our emissions of greenhouse pollution, the President has
continued old projects and instilled new plans. They are to:
Reduce carbon pollutions from power plants, accelerate clean energy leadership,
build a 21st century transportation sector, cut energy waste in homes, businesses, a
and factories, support climate-resilient investments, rebuild and learn from
Superstorm Sandy, launch an effort to create sustainable and resilient hospital,
maintain agricultural productivity, provide tools for climate resilience, work
with other countries to take action to address climate change, and lead efforts to
address climate change through international negotiations. (President Obama
June 25, 2013)
It is encouraging to see that steps are being taken to mitigate greenhouse gasses both
nationally and internationally, and to try to reduce the harmful consequences that already exist.
Unfortunately, the beneficial progress continues to meet resistance. A factor that usually causes
such delays is the motivation to persuade people to participate. This is why I propose to mitigate
greenhouse gasses by converting the greenhouse gasses into energy. Energy is an easy
conversion into money, and financial gain is a great motivator. By converting greenhouse gasses
into energy we can remove the existing excess greenhouse gasses and capture the newly
produced gasses, and in turn profit from the mitigation of these gasses. The profit generated
would hopefully be an incentive to motivate action.
4.
Carbon Dioxide
In 2007, Carbon dioxide emissions were 77% of the total volume of anthropogenic
greenhouse gasses that entered the atmosphere (see fig. 1) (“Greenhouse Gas Emissions:
Greenhouse Gases Overview”). So, knowing what the individual gas is, how that gas is created
or what is the source of the gas, and how to mitigate the gas is important.
Fig. 3 Carbon cycle with anthropogenic addition. "Carbon Cycle". Illustration. 20 Feb. 2011.
Cycles of Matter. CK-12 Foundation. Web. 07 Sept. 2013.
What is Carbon Dioxide (CO2)? It is a gas that is a natural chemical in the Earth's carbon
cycle, but it is a natural cycle that humans have altered by adding more CO2 (see fig. 3). This
excess CO2 from humans diminishes the earth's flora and ocean water's ability to absorb it.
(“Greenhouse Gas Emissions: Greenhouse Gases Overview”). The lifetime of carbon dioxide's
in the atmosphere ranges from 50 to 200 hundred years (“Greenhouse Gas Emissions:
Greenhouse Gases Overview”).
The sources of excess
carbon dioxide comes from
transportation, energy supply,
residential and commercial
buildings, industry, agriculture,
forestry, waste and waste water
(see fig. 4). It enters the
atmosphere through burning
fossil fuels (coal, natural gas and
oil), solid waste, trees and wood
products, and also as a result of
certain chemical reactions (e.g.,
manufacture of cement) (U.S
Environmental Protection
Agency ES-8–ES-12).
Fig. 4 Sources of CO2 emissions. "Sources of World's CO2
Emissions". Graph. 21 Oct. 2008. Frontline: Sources of
World's CO2 Emissions. WGBH Educational Foundation.
Web. 03 Sept. 2013.
Carbon dioxide is the greenhouse gas that receives the most attention worldwide to
reduce and mitigate due to the excessive amount that is anthropologically produced. A few
suggested ways to convert carbon dioxide into energy is: reforestation, algae, solar synthetic fuel,
converting it into methanol, liquid light, bacteria, and liquid fuel.
Reforestation is not as simple as it might conceptually seem, because while trees are an
excellent at absorbingCO2, one has to be careful to not create a monocrop and reduce
biodiversity. Also when trees fall they release the CO2 they had absorbed, so it is not a
permanent reduction of CO2. It is a temporary reduction until the trees are used for energy or
other wood-related products. (Dallas 58)
Carbon dioxide can also be converted by algae; “algae naturally absorbs CO2 through
photosynthesis” (“Clean Tech, Clean Profits” 171). There are various methods utilizing algae to
convert CO2 into energy. Some proposals suggest using tubes filled with algae affixed to
buildings; the algae from these tubes would be harvested before they start to decompose so that
they will not release the captured CO2 (“Clean Tech, Clean Profits” 171). This algae is
profitable, because it can be used for biofuel or “feedstock for the production of a fertilizer that
sequesters the carbon” (“Clean Tech, Clean Profits” 171). There is a real focus on algae usage
for energy, because algae has a “high energy content with a value per unit mass at 18.5 to 35
MJ/kg, that rivals that of coal (which averages at 24 MJ/kg)” (“Clean Tech, Clean Profits” 171).
At the University of Delaware Chemist Joel Rosenthal and doctoral student John
DiMeglio have converted CO2 into a synthetic fuel. They discovered that bismuth can convert
carbon dioxide into carbon monoxide, which is an extremely energy rich chemical that has many
uses. Also bismuth is a relatively inexpensive catalyst, which can use solar energy for the
conversion process. The outcome of this conversion, carbon monoxide, can be used as synthetic
fuels to power cars, houses, and businesses. (Bryant)
In Canada, at the University Laval in Quebec City, a team lead by Professor Frederic-
Georges Fontaine developed an effective way to convert CO2 into methanol that can be used as
fuel for vehicles. They wanted to develop a simple conversion method that could be
accomplished in a single step. This catalytic conversion process requires a source of hydrogen
and chemical energy; the researchers used the hydroborane (BH3) compound as their hydrogen
and chemical energy source. Also they found that the chemicals borane and phosphine are an
effective catalyst to accomplish the conversion. Their conversion method resulted in a reaction
that is twice as effective as the best known catalyst, while producing little waste. In addition,
this chemical reaction does not damage to the catalyst, so it can be reactivated by a new
substrate. (Huppe)
At Princeton University Andrew Borcarsly, the founder of the New Jersey company
Liquid Light, along with Emily Cole are the innovators of a process that turns carbon dioxide
into fuels and industrial chemicals (Zandonella). The technology that Liquid Light uses is taking
“CO2 and mix it in a water-filled chamber with an electrode and a catalyst. The ensuing
chemical reaction converts CO2 into a new molecule, methanol, which can be used as a fuel, an
industrial solvent or a starting material for the manufacturing of other chemicals” (Zandonella).
To create this reaction and result the company uses sunlight to conduct the process. Also, with
this new technology they discovered that “they could turn CO2, which contains only one carbon,
into a compound with a carbon-carbon bond. This carbon-carbon bond compound vastly
increases the possibilities for creating commercial applications” (Zandonella).
Meanwhile researchers at the University of Minnesota have created a process that “uses
two types of bacteria to create hydrocarbons from sunlight and carbon dioxide. These
hydrocarbons can in turn be made into fuel, which the scientists are calling renewable
petroleum” (Coxworth). It took teamwork between departments and colleges to discover and
complete this finding. They found:
That Synechococcus a photosynthetic bacterium adheres to carbon dioxide in
sunlight and then converts that CO2 to sugars. Those sugars are then passed on to
another bacteria Shewanella which consumes them and produces fatty acids.
University of Minnesota biochemistry graduate student Janice Frias discovered
how to use a protein to transform the fatty acids into ketones, a type of organic
compound. Her colleagues in the university's College of Science and Engineering
have developed a catalytic technology that converts those ketones into diesel fuel
(Coxworth).
A diesel fuel that diminishes greenhouse gasses and is not from fossil fuel is a winning
combination.
Scientific research is being conducted at the University of California, Los Angeles where
a team has “genetically engineered a microorganism that converts carbon dioxide into isobutanol
and 3-methyl-1-butanol, both of which could be used as a fuel source for cars, or other
combustion engines” (Anthony). The microorganism is called “ Ralstonia eutropha H16”
(Anthony) and this bacterium “uses electricity from solar energy to fixate carbon dioxide into
alcohols and feasts on the formic acid to produce the combustible alcohol” (Anthony). Once
again successful scientific exploration to transform carbon dioxide into energy has been
achieved.
These successful methods in converting the excessive greenhouse gas, carbon dioxide,
into a beneficial by-product hopefully will encourage motivation and continuation in advancing
these energy sources. All these processes that were discussed for carbon dioxide are carbon
neutral, or better yet carbon negative. It is definitely an important and encouraging start to the
mitigation of greenhouse gasses.
5.
Methane
By 2011, 14% of the total volume of anthropogenic greenhouse gasses were comprised
of methane emissions (see fig. 1) (“Greenhouse Gas Emissions: Greenhouse Gases Overview”).
Even though methane gas contributes only 14% of the greenhouse gasses it is more potently
harmful than carbon dioxide. Knowledge of this greenhouse gas is vital in the mitigating of its
contribution to greenhouse effects.
Methane (CH4) is a natural gas and is naturally absorbed by the soil and chemical
reactions in the atmosphere, but over 60% of total CH4 emissions come from human activities
and this overloads the earth's natural mitigation processes (see fig. 5) (“Greenhouse Gas
Fig. 5 Methane cycle with anthropogenic addition. "Methane Cycle". Illustration. 2010. Global
Warming Gallery. Encyclopaedia Britannica, Inc. Web. 07 Sept. 2013.
Emissions: Greenhouse Gases Overview”). Methane resides approximately twelve years in the
atmosphere, but unfortunately it is more efficient at trapping radiation than carbon dioxide. In
fact, “methane is more than 20 times as effective as CO2 at trapping heat in the atmosphere over
a 100-year period” (“U.S Environmental Protection Agency ES-12).
The sources
of methane are:
production and
transport of coal,
natural gas, an oil,
livestock and other
agricultural
practices, and by the
decay of organic
waste in municipal
solid waste landfills
and wetlands (see
fig. 6)(U.S
Fig. 6 Sources of Anthropogenic Methane in 2000. "Global Anthropogenic
CH4 Budget by Source in 2000". Diagram. 2007. What the deep-sea and
cows have in common. Bamfield Marine Sciences Centre. Web. 07 Sept.
Protection Agency
2013.
ES-12-ES-13). As noted previously, methane is a naturally produced gas, but the majority of
Environmental
methane is generated by human activities. Anthropogenic methane is more controllable and
easier to manipulate than natural methane; this enables the conversion of methane into energy
through the processes of capture, digestor, decomposition, and gobar gas.
One form of converting methane into energy is by capturing the methane gas at the
formation source, and then transporting it through pipelines just like any other usable natural gas.
Methane is “a prime component of natural gas, and where there is coal or oil, there are often
large deposits of gas. The gas is captured and piped to urban areas for commercial and
residential use” (Turner 151).
Another way to capture and use methane as energy is through the process of a digestor
(see fig. 7). In a digestor, the methane gasses from vegetable, animal, and human waste is
captured and contained; this stored gas can be piped for energy purposes (Howell 183). This is a
viable option for energy as it is continuous, and the waste material source that emits methane is
limitless. The digestor applications in converting methane gasses into useable energy is not only
an option for commercial use, but personal use, too (Howell 194).
Fig. 7 Methane digestor. "Basic Methane Production and Storage". Graph. 1979. Your Solar
Energy Home : Including Wind and Methane Applications. Pergamon Press. Print.
Methane gasses are already being successfully produced as useable commercial energy
through the decomposition of organic matter in landfills as useable commercial energy . The
“trash decomposes (or rots) in landfills creating methane gas; the methane rises to the top of the
landfill and is collected in pipes. The pipelines carry the methane to its destination and is burned
to produce heat or generate electricity” (see fig 8)("Methane Capture and Use"). The process of
using methane from landfills is of high interest, because “landfill gasses are a recognized
renewable energy resource. The gas serves as a base-load renewable energy for many utilities,
and landfill gasses are a competitive renewable resource” (Rajaram 23). This ecologically
beneficial method of mitigating methane and converting the gas into profitable energy is already
being utilized. “Germany produces enough electricity from biogas to power 3.5 million homes”
("Methane Capture and Use"). Sweden has been “operating a biogas-powered train since 2005; it
shuttles passengers between two cities that are 75 miles apart” ("Methane Capture and Use").
These successful methods of mitigating methane into usable energy is encouraging and hopefully
motivating. It is a winning combination with the outcome being profitable for humans and the
earth.
Fig 8 Capturing methane to convert into energy. "Landfill Methane Capture". Illustration. 21
June 2013. Methane Capture and Use. EPA. Web. 07 Sept. 2013.
Methane gas is also used as Gober gas; another eco-friendly alternative gas. Gobar gas is
a term for methane gas that is generated from cow manure and other waste. The process is
relatively simple and does not require sophisticated equipment or skill. The methane from the
waste and manure is captured, and is used for energy. (Dandekar 887-93)
The conversion of methane gasses into usable energy is proven and is relatively simple
with a profitable outcome: energy.
6.
Nitrous Oxide
Nitrous oxide (NO2) emissions by 2011 were 8% of the total volume of anthropogenic
greenhouse gasses that went up into the atmosphere globally (see fig. 1) (“Greenhouse Gas
Emissions: Greenhouse Gases Overview”). Even though nitrous oxide is a smaller percent of the
total of greenhouse gasses than carbon
dioxide and methane it is more potent
than both, and it lasts much longer in the
atmosphere. A basic understanding of the
greenhouse gas is essential to understand
the importance in its mitigation.
Nitrous oxide is a natural gas that
the earth produces. Nitrous oxide
circulates through many ecosystems that
is called the nitrogen cycle (see fig. 9).
The nitrogen cycle is the natural
Fig. 9 Natural nitrogen cycle. "Nitrogen Cycle".
Illustration. 20 Feb. 2011. Cycles of Matter. CK-12
Foundation. Web. 07 Sept. 2013
circulation of nitrogen that is in the soils, animals, plants, waters, and then into the atmosphere
(Greenhouse Gas Emissions: Greenhouse Gases Overview”). However, 40% of nitrous oxide
emissions come directly from human activities such as: agriculture, fossil fuel combustion,
waste-water management, industrial processes, and transportation (see fig. 10)(U.S
Environmental Protection Agency ES-14-ES-15). The primary source of these anthropogenic
emissions come from agriculture, especially from fertilizers (U.S Environmental Protection
Agency ES-15).
Fig. 10 Sources of nitrogen oxide. "Nitrous Oxide by Sector". Diagram. 11 Oct. 2011. GCSE &
A Level Geography. Tutor2u. Web. 07 Sept. 2013.
Nitrogen oxide remains in the atmosphere for 120 years on average and is “approximately
300 times more powerful than CO2 at trapping heat in the atmosphere” (U.S Environmental
Protection Agency ES-14). Therefore, even one pound of nitrous oxide is a powrful contributor
to global climate warming.
One way of reducing the atmopsheric content of NO2 is to convert it into useable energy
or biofuel through the process of biomass combustion. Converting biomass into biofuel through
combustion results in neutral emissions, and produces energy while capturing and eliminating
waste that would otherwise pollute the atmosphere and environment (Hunter et. all 136). Any
method that generates neutral greenhouse emissions is a step in the right direction, because doing
nothing to mitigate greenhouse gasses leads down a cataclysmic path.
7.
Fluorinated Gasses
`In 2011, fluorinated gasses emissions were 1% of the total volume of anthropogenic
greenhouse gasses that went up into the atmosphere (see fig. 1)(“Greenhouse Gas Emissions:
Greenhouse Gases Overview”). One percent might not seem like much in comparison to the
other gasses, but these are the most potent and destructive of all the greenhouse gasses. In fact,
these gasses have no natural source; they are fully and completely man-made (“Greenhouse Gas
Emissions: Greenhouse Gases Overview”).
Fluorinated gasses are divided into three groups: “Hydrofluorocarbons (HFCs),
perfluorocarbons (PFCs), and sulfur hexafluoride (SF6)” (U.S Environmental Protection Agency
1-3). Their life-span in the atmosphere varies; HFC's life-span is from 1 to 270 years, PFCs is
800 to 50,000 years, and SF6 is up to 3,200 years (“Greenhouse Gas Emissions: Greenhouse
Gases Overview”). These gasses are so destructive that just one pound of HFC has the warming
capability of 140 to 11,700 times more than one pound of carbon dioxide. One pound of PFC
has the warming capability of 6,500 to 9,200 times that of one pound of carbon dioxide, and one
pound of SF6 has a staggering 23,900 times more global warming capability than one pound of
carbon dioxide (“Greenhouse Gas Emissions: Greenhouse Gases Overview”).
The sources of these harmful fluorinated gasses are varied, but all are man-made. For
example, hydrofluorocarbons are used in refrigerants, aerosol propellants, solvents, and fire
retardants (see fig. 11) (“Greenhouse Gas Emissions: Greenhouse Gases Overview”).
Perfluorocarbons “ are compounds produced as a by-product of various industrial processes
associated with aluminum production and the manufacturing of semiconductors” (see fig. 11)
(U.S Environmental Protection Agency ES-15). While sulfur hexafluoride is “used in
magnesium processing and semiconductor manufacturing, as well as a tracer gas for leak
detection, and used in electrical transmission equipment, including circuit breakers” (see fig. 11)
(U.S Environmental Protection Agency 1-6).
Fig. 11 The Sources of flourinated gasses. The number behind each gas is the specific chemical
that is created by the human sources. "Human sources of fluorinated gas". Diagram. 2010. What
are the main sources of fluorinated gas emissions? Whatsyourimpact.eu.org 2013. Web. 07 Sept.
2013.
Unfortunately, since these are man-made chemicals, and rather new to the greenhouse gas
family, there has not been a discovered method to convert these gasses into energy. The only
option is to eliminate these destructive and deadly gasses by not producing them. We created
them, we are the only source for them, and since we can not convert them into useful energy,
then we simply should not create them.
8.
Conclusion
Hopefully by providing a concise source of information about greenhouse gasses, and the
ensuing hazardous effects caused by excess anthropogenic greenhouse gasses, along with the
importance of their mitigation will generate the motivation to reduce these gasses by converting
them into profitable energy. In this paper I have given detailed data about each gas and the
various current methods of converting them into an energy source. I hope that condensing all the
various scientific research data into a concise and comprehensive paper has illuminated this
global problem and the need for a expedient resolution. Thankfully, there are successful methods
for mitigating greenhouse gasses. The information I have compiled has shown that the
conversion of these excess anthropogenic greenhouse gasses into energy has been a successful
method to mitigate these gasses. This information should be used as motivation to implement
these current methods and encourage the development of future processes of mitigation into
profitable energy.
For future research a cost-benefit and financial profile of the various ways to mitigate
greenhouse gasses needs to be comprehensively and concisely complied into an understandable
document to help implement the processes. The combination of this foundational paper and a
financially-focused paper will hopefully motivate the implementation of greenhouse gas
generated energy. The implementation of greenhouse generated energy will create new job
opportunities in a newly invented commercial job market, which will be ecological and
financially beneficial. At the same time, these energy companies will be mitigating the current
greenhouse gasses and preventing any further harmful consequences . It is a win-win situation
for the earth and mankind.
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Appendix
Environmental Protection Agency's Action Plan on Climate Change
(“What Is EPA Doing About Climate Change?”)
•
“Collecting Emissions Data: This information helps policy makers, businesses, and the
EPA track greenhouse gas emission trends and identify opportunities for reducing
emissions and increasing efficiency.
•
Obtaining Reductions:
◦
Developing Common-sense Regulatory Initiatives: EPA is developing common sense
regulatory initiatives to reduce GHG emissions and increase efficiency. For example,
the EPA's vehicle greenhouse gas rules will save consumers $1.7 trillion at the fuel
pump by 2025, and eliminate six billion metric tons of GHG pollution.
◦
Partnering With the Private Sector: Through voluntary energy and climate programs
the EPA's partners reduced over 345 million metric tons of greenhouse gases in 2010
alone (equivalent to the emissions from 81 million vehicles) and saving consumers
and businesses of about $21 billion.
◦
Reducing EPA's Carbon Footprint: The EPA is monitoring emissions from its own
energy use and fuel consumption. They are working to reduce greenhouse gas
emissions by 25% by 2020.
•
Evaluating Policy Options, Costs and Benefits: The EPA conducts economy wide
analysis to understand the economic impacts and effectiveness of proposed climate
policies. Advancing the Science: The EPA contributes to world-class climate research
through the U.S. Global Change Research Program and the Intergovernmental Panel on
Climate Change. The EPA's Office of Research and Development conducts research to
understand the environmental and health impacts of climate change, and to provide
sustainable solutions for adapting to and reducing the impact from a changing climate.
•
Partnering Internationally: The EPA is engaged in a variety of international activities to
advance climate change science, to monitor our environment, and promote activities that
reduce greenhouse gas emissions. The EPA establishes partnerships, provides leadership,
and shares technical expertise to support these activities.
•
Partnering With States, Localities, and Tribes: The EPA's State and Local Climate and
Energy Program provides technical assistance, analytical tools, and outreach support on
climate change issues to state, local, and tribal governments.
•
Helping Communities Adapt: The EPA's Climate Ready Estuaries and Climate Ready
Water Utilities programs help coastal resource managers and water utility managers
respectively plan and prepare for climate change.”